A Comparative Study on The Electrochemical Properties of Hydrothermal and Solid-State Methods in The NCM Synthesis for Lithium Ion Battery Application

Q4 Chemical Engineering ASEAN Journal of Chemical Engineering Pub Date : 2022-12-29 DOI:10.22146/ajche.74209

S. Pradanawati, E. Nursanto, Afif Thufail, Ahmad Zaky Raihan, S. Sugianto, H. Oktaviano, Hanida Nilasary, A. Subhan, Agung Nugroho

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Abstract

In this article, we report and compare the synthesis method of the active cathode materials based on nickel‐cobalt‐manganese (NCM) for lithium-ion battery application. We evaluate the hydrothermal and solid-state reaction method in NCM-622 synthesis, the material characterizations, and the battery performance. Based on the analytical results using X-ray diffraction (XRD), particles synthesized using hydrothermal and solid-state methods exhibit a highly crystalline NCM phase. NCM particles synthesized using solid-state reaction exhibit high-rate performance up to 10 C. The electrochemical impedance spectroscopy analysis shows that the charge transfer resistance (Rct) of NCM synthesized by the solid-state reaction (SSR) method was 25.9% lower than hydrothermal. Meanwhile, the ionic diffusivity of the SSR sample was 38.5% higher than the hydrothermal sample. These two factors lead to better performance when tested in a lithium-ion battery.

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水热法和固态法在锂离子电池NCM合成中电化学性能的比较研究

在本文中，我们报道并比较了用于锂离子电池应用的基于镍钴锰（NCM）的活性阴极材料的合成方法。我们评估了NCM-622合成中的水热和固态反应方法、材料表征和电池性能。基于X射线衍射（XRD）的分析结果，使用水热和固态方法合成的颗粒显示出高度结晶的NCM相。通过固态反应合成的NCM颗粒表现出高达10C的高速率性能。电化学阻抗谱分析表明，通过固态反应（SSR）方法合成的NCM的电荷转移电阻（Rct）比水热法低25.9%。同时，SSR样品的离子扩散率比水热样品高38.5%。当在锂离子电池中测试时，这两个因素会带来更好的性能。

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ASEAN Journal of Chemical Engineering Chemical Engineering-Chemical Engineering (all)

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1.00

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